JP2015079200A - Imaging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain both of increase in the number of continuous shooting images per a unit time and quietness upon shooting in an imaging device.SOLUTION: An imaging device according to the present invention includes: an amount-of-light adjustment device that drives a plurality of blade members by a stepping motor; and a control unit that outputs a drive pulse signal for driving the stepping motor. For controlling the amount-of-light adjustment device, the imaging device includes a storage unit that stores first amount-of-light adjustment device control information and second amount-of-light adjustment device control information, which shows a relation between a target AV value and the number of drive pulse signals input to the stepping motor. When a still image is continuously shot by the imaging device, the control unit controls the amount-of-light adjustment device using the second amount-of-light adjustment device control information, and when a video image is shot by the imaging device or only one sheet of the still image is shot, the second amount-of-light adjustment device control information is used to control the amount-of-light adjustment device.

Description

  The present invention relates to an imaging apparatus including a light amount adjusting device that drives a plurality of blade members by a stepping motor.

  Some lens devices provided in an imaging apparatus such as a still camera or a video camera include a light amount adjusting device called a so-called diaphragm device on an optical path through which a light beam passes in order to perform light amount adjustment.

  As a light amount adjusting device, as disclosed in, for example, Japanese Patent Application Laid-Open No. 2011-107584, a plurality of blade members arranged around the optical axis are rotated around an axis parallel to the optical axis to open an opening. The structure which changes the aperture of is known. In the light amount adjusting device disclosed in JP 2011-107584 A, the blade member is driven by a stepping motor.

JP 2011-107584 A

  In an imaging apparatus that captures still images, it may be required to increase the number of continuous shots per second. For this reason, in the light quantity adjusting device, it is desired to reduce the time required from the open state to the minimum aperture state. On the other hand, the imaging device may be required to have quietness during the imaging operation, and both quietness and high-speed operation of the light amount adjusting device are required.

  The present invention has been made in view of the above points, and an object of the present invention is to achieve both an increase in the number of continuously shot images per unit time and quietness during shooting in an imaging device.

  An imaging device of one embodiment of the present invention includes a lens device and the lens device, and each of the plurality of blade members is driven by driving a plurality of blade members disposed around the optical axis by a stepping motor. An image pickup apparatus comprising: a light amount adjusting device capable of changing a diameter of an opening formed by an edge portion; and a control unit that outputs a driving pulse signal for driving the stepping motor, wherein the light amount adjusting device is A storage unit for storing first light amount adjustment device control information and second light amount adjustment device control information representing a relationship between a target AV value for control and the number of drive pulse signals input to the stepping motor; The control unit controls the light amount adjustment device using the second light amount adjustment device control information when continuously capturing still images with the image pickup device, and controls the image pickup device. Controlling the light amount adjustment device using the second light amount adjuster control information in the case of imaging only one case or still image captures a moving me.

  According to the present invention, in the imaging apparatus, it is possible to achieve both an increase in the number of continuous shots per unit time and quietness during shooting.

It is a perspective view of a light quantity adjustment device. It is a disassembled perspective view of a light quantity adjustment apparatus. It is the figure seen from the arrow [3] direction of FIG. 1, Comprising: It is a front view of a light quantity adjustment apparatus. It is the elements on larger scale which expand and show the area | region shown by code | symbol [4] of FIG. It is a top view of a blade member. It is a side view of a blade member. It is a perspective view of a torsion spring. It is the figure which showed only the blade member and the rotational drive board in the open state. It is the figure which showed only the blade member and the rotational drive board in the minimum aperture state. It is the elements on larger scale which show the relationship between a blade member and a rotation drive plate in the viewpoint fixed with respect to the rotation drive plate. It is a block diagram which shows the structure of an imaging device. It is a flowchart which shows the process which selects the light quantity adjustment apparatus control information at the time of imaging. It is a graph for demonstrating light quantity adjustment apparatus control information.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In the drawings used for the following description, the scale of each component is made different in order to make each component recognizable on the drawing. It is not limited only to the quantity of the component described in (1), the shape of the component, the ratio of the size of the component, and the relative positional relationship of each component.

  First, the configuration of the light amount adjustment device 10 included in the imaging device 30 according to the embodiment of the present invention will be described. FIG. 1 is a perspective view showing an appearance of a light amount adjusting apparatus according to an embodiment of the present invention. FIG. 2 is an exploded perspective view of the light amount adjusting device of FIG. FIG. 3 is a front view of the light amount adjusting device as viewed from the direction of the arrow [3] in FIG. FIG. 4 is a partially enlarged view showing a part of FIG. 3 (area indicated by reference numeral [4]) in an enlarged manner.

  As shown in FIGS. 1 to 3, etc., the light amount adjustment device 10 of the present embodiment includes a fixed frame member 11, a rotation drive plate 12, a plurality of blade members 13, a lid member 14, a torsion spring 15, It is mainly composed of a stepping motor 16, an urging spring 18 that is a coil spring, a position sensor 20, and the like.

  The light amount adjusting device 10 constitutes a so-called diaphragm mechanism provided in a lens device of an imaging device such as a still camera or a video camera. The light amount adjusting device 10 has an opening 10a through which the optical axis L in the lens device passes. The light amount adjusting device 10 includes a plurality of blade members 13 that are rotatable around an axis parallel to the optical axis L disposed around the opening 10a, and advances and retracts the plurality of blade members 13 into the opening 10a. Thus, the aperture through which the light beam along the optical axis L can pass is changed.

  Among the constituent members of the light amount adjusting device 10, the fixed frame member 11 is a basic constituent member in the light amount adjusting device 10. The fixed frame member 11 is formed in a substantially annular shape as a whole, and has a substantially circular opening 11a at a substantially central portion thereof.

  Specifically, the fixed frame member 11 is formed by an annular flat surface portion 11p, an outer peripheral wall surface 11m, and an inner peripheral wall surface 11n. Here, the outer peripheral wall surface 11m is a wall-shaped portion formed so as to surround the outer peripheral edge portion of the annular flat surface portion 11p. The inner peripheral wall surface 11n is a wall-shaped portion formed so as to surround the inner peripheral edge portion of the annular flat surface portion 11p. With this configuration, the fixed frame member 11 forms an annular housing having an internal space formed by the annular flat surface portion 11p, the outer peripheral wall surface 11m, and the inner peripheral wall surface 11n. A rotation drive plate 12 and a plurality of blade members 13 are accommodated in the internal space of the fixed frame member 11 (details will be described later). Moreover, the site | part which opposes the annular plane part 11p of the fixed frame member 11 is opening, and the cover member 14 is arrange | positioned so that this opening site | part may be covered. As described above, the fixed frame member 11 and the lid member 14 form a casing portion of the light amount adjusting device 10.

  A plurality of stepping motors 16 (in this example) are provided on one side surface of the annular flat surface portion 11p of the fixed frame member 11 on the outer surface side opposite to the side where the internal space portion is formed. Two) screws 17 are fixed. For this purpose, a plurality (two in this example) of screw holes 11d are formed in the vicinity of the attachment part of the stepping motor 16 in the annular plane part 11p.

  The stepping motor 16 is an electric actuator for rotating the rotational drive plate 12 by a predetermined amount in a predetermined rotation direction at a predetermined timing. In the present application, as an example, the stepping motor 16 has a rotating drive shaft. The drive shaft of the stepping motor 16 is disposed so as to penetrate through a through hole 11f formed in a predetermined portion of the annular flat surface portion 11p of the fixed frame member 11. A pinion gear 16 a is fixed to the tip end side of the drive shaft of the stepping motor 16. The pinion gear 16 a meshes with the sector gear 12 d of the rotary drive plate 12. With this configuration, the rotational driving force of the stepping motor 16 is transmitted to the rotational drive plate 12 via the drive shaft, the pinion gear 16a, and the sector gear 12d. In response to this rotational driving force, the rotational driving plate 12 is configured to be rotationally driven by a predetermined amount in a predetermined direction.

  The rotation drive plate 12 is a blade drive member provided to receive the driving force of the stepping motor 16 and drive the plurality of blade members 13. The entire rotation drive plate 12 is formed in a substantially annular shape having a slightly smaller diameter than the fixed frame member 11 and has a substantially circular opening 12a at a substantially central portion thereof. The rotation drive plate 12 is disposed so as to be rotatable with respect to the fixed frame member 11 in the internal space of the fixed frame member 11.

  A sector gear 12d is formed at a portion of the outer peripheral edge of the rotary drive plate 12. As described above, the pinion gear 16a of the stepping motor 16 is engaged with the sector gear 12d.

  A coil spring locking portion A12b that locks one end of the urging spring 18 is formed at a portion in the vicinity of the outer peripheral edge of the rotary drive plate 12. The coil spring locking portion A12b is an axial portion formed so as to protrude in a direction substantially orthogonal to the radial direction of the rotary drive plate 12. The tip of the coil spring locking portion A12b is formed in a substantially hook shape so that one end of the biasing spring 18 can be locked.

  Correspondingly, a through groove portion 11b having a predetermined length along the radial direction is formed at a predetermined portion of the annular flat surface portion 11p of the fixed frame member 11. As a result, when the rotary drive plate 12 is housed in a predetermined portion of the internal space of the fixed frame member 11, the coil spring locking portion A12b penetrates the through groove portion 11b and the outer surface side of the fixed frame member 11 (circular circle). It protrudes and is arrange | positioned in the ring plane part 11p. In this state, when the rotary drive plate 12 is rotated by receiving the driving force of the stepping motor 16, the coil spring locking portion A12b is configured to move along the through groove portion 11b.

  On the other hand, on the outer surface side of the fixed frame member 11 (one side surface side of the annular flat surface portion 11p), a coil spring engagement projecting in the vicinity of the through groove portion 11b in the same direction as the coil spring locking portion A12b. Stop part B11c is formed. The tip of the coil spring locking portion B11c is formed in a substantially hook shape so that the other end of the biasing spring 18 can be locked. The other end of the biasing spring 18 is locked to the coil spring locking portion B11c.

  As described above, one end of the urging spring 18 that is an urging member such as a coiled coil spring is locked to the coil spring locking portion A12b. With this configuration, the rotation drive plate 12 disposed so as to be rotatable with respect to the fixed frame member 11 is always urged toward one rotation direction by the urging spring 18. In this case, the biasing direction of the rotary drive plate 12 by the biasing spring 18 is, for example, a direction in which the plurality of blade members 13 driven by the rotation of the rotary drive plate 12 narrows the optical path diameter (referred to as a closing direction). . In addition to this example, the biasing direction of the rotary drive plate 12 by the biasing spring 18 may be a direction in which the same optical path diameter is opened (referred to as an opening direction).

  On the other hand, a plurality of cam grooves 12c having a predetermined cam curve are formed in a planar portion forming an annular shape of the rotary drive plate 12. In the plurality of cam grooves 12c, driven pins 13c (described later) of the plurality of blade members 13 are cam-fitted. That is, the plurality of cam grooves 12c serve as driving units that drive the plurality of blade members 13, respectively. Therefore, the plurality of cam grooves 12 c are formed in the same number as the plurality of blade members 13. In the present embodiment, an example in which seven blade members 13 are arranged is shown. Therefore, in this example, seven cam grooves 12c are formed.

  The plurality of blade members 13 are arranged so as to overlap each other, thereby forming a substantially circular opening, and each of the blade members 13 performs a predetermined movement, thereby changing the aperture diameter and adjusting the amount of light passing therethrough. It is a light shielding member. Each of the plurality of blade members 13 is configured by, for example, a thin sheet member. As described above, in the present embodiment, an example constituted by seven blade members 13 is shown.

  Each of the plurality of blade members 13 is pivotally supported on a support shaft (not shown in FIGS. 1 and 2) of the fixed frame member 11 so as to be rotatable about each base. And stored in the internal space. At this time, each of the driven pins 13 c of the plurality of blade members 13 is cam-fitted in each of the plurality of cam grooves 12 c of the rotary drive plate 12.

  In this manner, the opening portion of the fixed frame member 11 is covered with the lid member 14 in a state where the rotation drive plate 12 and the plurality of blade members 13 are accommodated in the internal space of the fixed frame member 11. In this case, the fixed frame member 11 and the lid member 14 are fastened and fixed by, for example, a plurality of screws 19 or the like.

  The lid member 14 is formed in a substantially annular shape having substantially the same diameter as the fixed frame member 11, and has a circular opening 14a at a substantially central portion thereof. The lid member 14 covers the opening portion of the fixed frame member 11 and prevents members (such as the rotary drive plate 12 and the plurality of blade members 13) housed in the internal space of the fixed frame member 11 from dropping off. It serves as a restraining member.

  Each driven pin 13c (described later) of each blade member 13 accommodated in the internal space is engaged with the inner surface side of the lid member 14 (the surface facing the internal space of the fixed frame member 11). A bottomed groove 14b for guiding the movement of the 13 driven pins 13c is formed. The lid member 14 is formed with a plurality of cutout portions 14c (the same number as the blade members 13) for exposing the vicinity of the base end portion that is the rotation center of each blade member 13 housed in the internal space. Yes.

  Further, a torsion spring locking portion A 14 d for hooking one arm 15 b (described later; see FIG. 4) of the torsion spring 15 and a main body portion 15 c of the torsion spring 15 are provided in the vicinity of the notch portion 14 c of the lid member 14. A spring support shaft 14e for winding and holding is provided (not shown in FIGS. 1 and 2; see FIGS. 3 and 4). The torsion spring locking portion A14d and the spring support shaft 14e are formed so as to protrude outward from the outer surface side of the flat surface portion of the annular shape of the lid member 14. The tip of the torsion spring locking portion A14d is formed in a substantially hook shape so that one arm 15b of the torsion spring 15 can be locked. One arm 15b of the torsion spring 15 is locked to the torsion spring locking portion A14d. The tip of the spring support shaft 14e is formed in a substantially hook shape so that the main body 15c of the torsion spring 15 does not fall out.

  The torsion spring 15 is a biasing member that always biases the blade member 13 in one direction so that the diameter of the plurality of blade members 13 is closed or opened. In the present embodiment, it is assumed that the direction of the urging force of the torsion spring 15 is set so that the blade member 13 is in the closing direction.

  Here, the detailed configuration of the torsion spring 15 itself will be described with reference to FIG. FIG. 7 is an enlarged perspective view showing the torsion spring 15 applied to the light amount adjusting device 10 of the present embodiment in an enlarged manner.

  The torsion spring 15 has a main body 15c wound in a coil shape, one arm 15b extending from one end of the main body 15c, and another arm 15a extending from the other end of the main body 15c. Is formed. The torsion spring 15 is a biasing member that uses a biasing force in the torsional direction. One torsion spring 15 is provided corresponding to each of the plurality of blade members 13.

  As shown in an enlarged view in FIG. 4, the main body portion 15c of the torsion spring 15 is wound around the spring support shaft 14e. The spring support shaft 14e is disposed substantially coaxially with the support shaft provided on the fixed frame member 11 that rotatably supports the blade member 13. One arm 15 b of the torsion spring 15 is locked to a torsion spring locking portion A 14 d of the lid member 14, and the other arm 15 a is locked to a torsion spring locking portion B 13 e provided on the blade member 13.

  Further, the light amount adjusting device 10 of the present embodiment has a position sensor 20 that detects the position of the rotary drive plate 12. As the position sensor 20, for example, a photointerrupter or the like is applied. The position sensor 20 is arranged in a predetermined portion inside the housing portion in which the fixed frame member 11 and the lid member 14 are combined, that is, in a concave portion indicated by reference numeral 14f in FIG. And fixed to the casing. Correspondingly, a light-shielding blade 12e that acts on the position sensor 20 is formed on the outer peripheral edge of the rotary drive plate 12. And this light-shielding blade | wing part 12e is comprised so that it can pass between the light transmission / reception parts of the said position sensor 20. FIG.

  5 and 6 are enlarged views showing the blade member 13 applied to the light amount adjusting device 10 of the present embodiment. Among these, FIG. 5 is a plan view of the blade member 13. FIG. 6 is a side view of the blade member 13.

  As illustrated, the blade member 13 is a light shielding member formed of, for example, a thin plate-like sheet member as described above. The blade member 13 is formed in a substantially lunate shape and is cam-fitted into the main blade portion 13a which is the main portion of the blade member 13 and the cam groove 12c of the rotary drive plate 12 to drive the blade member 13. A driven pin 13c, a torsion spring locking portion B13e for locking the other arm 15a of the torsion spring 15, a support portion 13h having a through hole 13d through which the support shaft of the fixed frame member 11 passes, and the like. ing.

  The plurality of blade members 13 configured as described above are rotatably supported by a plurality of support shafts provided on the fixed frame member 11. This configuration will be specifically described as follows. In other words, for example, on the other side surface side (inner side surface of the internal space portion) of the annular flat surface portion 11p of the fixed frame member 11, the number of the support shafts corresponds to each of the plurality of blade members 13 (in this embodiment). 7) and are planted over the entire circumference at predetermined intervals in the radial direction.

  And the through-hole 13d of the support part 13h provided in the base part of each blade | wing member 13 is each penetrated with respect to each of said several spindle. Accordingly, the blade member 13 is pivotally supported so as to be rotatable about the support shaft 11e as a central axis. At this time, the blade member 13 is housed and disposed in the internal space of the fixed frame member 11. Therefore, the blade member 13 is housed and disposed in the inner space of the fixed frame member 11 so as to be rotatable within a predetermined range.

  Further, the blade member 13 is biased by the torsion spring 15 in the direction in which the main blade portion 13a approaches the optical axis L around the support shaft. In other words, the torsion spring 15 urges the blade member 13 in the narrowing direction.

  In this way, by urging each of the plurality of blade members 13 included in the light amount adjusting device 10 in the direction of narrowing by the plurality of torsion springs 15, the light amount adjusting device 10 is changed from the open state to a narrowed state of a predetermined AV value. In the case of transition, the repeatability of the stop position of the blade member 13 is improved.

  FIG. 8 is a view showing only the blade member 13 and the rotary drive plate 12 in a state where the amount of light passing through the light amount adjusting device 10 is maximized (open state). FIG. 9 is a view showing only the blade member 13 and the rotary drive plate 12 in a state where the amount of light passing through the light amount adjusting device 10 is minimized (minimum aperture state). FIG. 10 is an enlarged view for showing the relationship between the blade member 13 and the rotary drive plate 12 at a viewpoint fixed to the rotary drive plate 12.

  As shown in FIG. 10, when the rotary drive plate 12 and the fixed frame member 11 rotate relatively around the optical axis L, the blade member 13 is fixed by the engagement of the cam groove 12c and the driven pin 13c. It rotates around a support shaft provided on the frame member 11. The support shaft of the blade member 13 is parallel to the optical axis L, and the main blade portion 13a moves so as to approach or move away from the optical axis L when the blade member 13 rotates around the support shaft. In the light amount adjusting device 10, the shape of the opening through which the light beam can pass is determined by the edge portion 13i of the main blade portion 13a of the plurality of diaphragm blades 13 disposed around the opening 10a.

  As shown in FIG. 9, when the rotation drive plate 12 is driven by the stepping motor 16 in the closing direction (direction indicated by the arrow C in FIG. 9) around the optical axis L relative to the fixed frame member 11. The plurality of blade members 13 rotate in a direction in which the main blade portion 13a approaches the optical axis L, and the area of the opening through which the light beam can pass becomes narrow.

  Further, as shown in FIG. 8, the stepping motor 16 causes the rotation drive plate 12 to move relative to the fixed frame member 11 in the opening direction (indicated by an arrow O in FIG. 8) opposite to the closing direction around the optical axis L. When driven in the direction indicated by), the plurality of blade members 13 rotate in a direction in which the main blade portion 13a moves away from the optical axis L, and the area of the opening through which the light beam can pass is widened.

  The light amount adjusting device 10 having the configuration described above is disposed in the lens device 21 used for the imaging device 30. FIG. 11 is a block diagram illustrating a configuration of the imaging device 30.

  As an example in the present embodiment, the imaging device 30 has a form generally referred to as an electronic camera, a digital camera, or the like, and includes a lens device 21 including an imaging lens 22 that forms a subject image, and an imaging element 32. The camera main body 31 is provided. The imaging device 30 is configured to be able to convert an optical image (subject image) formed by the imaging lens 22 into an electrical signal by the imaging element 32 and to output it as electronic data. It should be noted that only a general configuration of the known configuration of the imaging device 30 will be described, and a detailed description thereof will be omitted.

  The camera body 31 includes an image sensor 32, a power supply unit 33, a control unit 34, a storage device 35, an image display device 36, and a touch panel (operation member) 37.

  The image sensor 32 is an image sensor such as a CCD or CMOS sensor. The imaging element 32 converts the optical image formed by the imaging lens 22 into an electrical signal.

  The power supply unit 33 includes any one of a primary battery, a secondary battery, and an AC adapter that can be connected to a commercial power supply, and is configured to supply power for driving each component of the imaging device 30. The power supply unit 33 may be configured to be detachable from the imaging device 30.

  The control unit 34 includes an arithmetic device (CPU), a storage device (RAM), an auxiliary storage device, an input / output device, and the like, and is configured to control the operation of the imaging device 34 based on a predetermined program. have. The control unit 34 is configured to be able to communicate with a lens control unit 23 of the lens device 21 described later via a lens communication unit 38.

  The storage device 35 is configured by a flash memory, a hard disk drive, or the like. The storage device 35 can store electronic data of an image captured by the image sensor 32.

  The image display device 36 includes a liquid crystal display device or an organic EL display device that can display an image. The image display device 36 performs live view display for sequentially displaying images picked up by the image pickup device 32 during the image pickup operation of the image pickup device 30, and changes settings such as the operation mode and shooting conditions of the image pickup device 30. Menu display for

  The touch panel 37 that is an operation member is disposed on the display surface of the image display device 36, and is configured to be able to detect a position touched by or close to one or more fingers or a stylus of the user. Has been. Note that the operation member included in the imaging device 30 is not limited to a touch panel type, and may be another type such as a dial switch or a push switch.

  The imaging device 30 also has a release switch 39 and a power switch 40. The release switch 39 is a push button switch, for example, and is used by the user to input an imaging instruction. The power switch 40 is, for example, a push button switch or a lever switch, and is used by the user to input instructions for starting and shutting down the imaging device 30.

  The lens device 21 includes an imaging lens 22, a light amount adjusting device 10, a focus lens driving unit 24, a lens control unit 23, and a storage unit 25.

  The lens device 21 may be in the form of an interchangeable lens of a so-called system camera that can be attached to and detached from the camera body 31, or may be fixed in the camera body 31. The imaging device 30 may be configured such that the lens device 21 and the imaging device 32 are configured as one unit, and the unit can be exchanged.

  In the lens device 21, the light amount adjusting device 10 is disposed on the optical path of the imaging lens 22. The focus lens driving unit 24 includes an electric actuator that drives a part or all of the lens group constituting the imaging lens 22 in parallel with the optical axis L.

  The lens control unit 23 includes an arithmetic device, a storage device, an auxiliary storage device, an input / output device, and the like, and controls operations of the light amount adjusting device 10 and the focus lens driving unit 24 based on a predetermined program. It has the composition to do. The lens control unit 23 can communicate with a control unit 34 included in the camera body 31 via the communication unit 26. The lens control unit 23 controls the operations of the light amount adjusting device 10 and the focus lens driving unit 24 in cooperation with the control unit 34 of the camera body 31.

  The storage unit 25 includes a flash memory or the like, and stores characteristic values such as a focal length and an open F value of the imaging lens 22 of the lens device 21. The storage unit 25 stores parameters necessary for the lens control unit 23 to control the operations of the light amount adjusting device 10 and the focus lens driving unit 24.

  Next, the operation of the imaging device 30 will be described. The flowchart shown in FIG. 12 is after the power switch 40 is operated and the imaging device 30 shifts from the power-off state to the on-state, and the release switch 39 is further pressed to input an imaging instruction from the user. This subroutine is executed when it is executed, or executed at an appropriate place in the main routine (not shown) of the imaging device 30. Note that the main routine that is executed after the imaging device 30 is started is the same as that of a known imaging device, and thus description thereof is omitted.

  The subroutine shown in FIG. 12 is a process for selecting the operation control mode of the light amount adjusting device 10 as described below during the imaging operation of the imaging device 30.

  The stepping motor 16 provided in the light amount adjusting device 10 rotationally drives the drive shaft (pinion gear 16a) at an angle proportional to the number of drive pulse signals input from the lens control unit 23. That is, in the light amount adjusting device 10, when driving (narrowing) the plurality of blade members 13 from the open state to a position where the target AV value is obtained, a predetermined number of drive pulse signals with respect to the target AV value are obtained. Needs to be input to the stepping motor 16.

  This information representing the relationship between the target AV value of the light amount adjusting device 10 and the number of drive pulse signals input to the stepping motor 16 is hereinafter referred to as light amount adjusting device control information. The light amount adjustment device control information is stored in the storage unit 25 provided in the lens device 21 and is referred to by the lens control unit 23 when the light amount adjustment device 10 is operated.

  The light amount adjustment device control information may be any information that represents the relationship between the target AV value and the number of drive pulse signals. For example, the light amount adjusting device control information may be a function of a straight line or a curve that continuously represents the relationship between the target AV value from the open state to the minimum aperture and the number of drive pulse signals. Further, for example, the light amount adjusting device control information includes table-like data including a finite number of target AV values from the open state to the minimum aperture, and the number of drive pulse signals respectively corresponding to the finite number of target AV values. It may be.

  Here, in the imaging device 30 of the present embodiment, a plurality of light amount adjustment device control information is stored in the storage unit 25. More specifically, two light amount adjustment device control information C2 of the first light amount adjustment device control information C1 and the second light amount adjustment device control information is stored in the storage unit 25.

  The first light amount adjusting device control information C1 and the second light amount adjusting device control information are shown as a graph in FIG. In FIG. 13, the horizontal axis represents the target AV value, and the amount of light decreases toward the right. Note that the target AV value in FIG. 13 is a difference (increase) with respect to the AV value in the open state, and is not an absolute value. That is, the case where the target AV value is 0 is the open state. In FIG. 13, the vertical axis represents the number of drive pulse signals to be driven from the open state. In FIG. 13, the first light amount adjusting device control information C1 is indicated by a broken line, and the second light amount adjusting device control information C2 is indicated by a one-dot chain line.

  As shown in FIG. 13, the first light quantity adjustment device control information C1 and the second light quantity adjustment device control information C2 have different drive pulse signal numbers for the same target AV value. Specifically, when the target AV value is the same, the number of drive pulse signals by the first light quantity adjustment device control information C1 is larger than that of the second light quantity adjustment device control information C2. That is, in the imaging device 30 of the present embodiment, the rotation angle of the stepping motor 16 differs between the first light amount adjustment device control information C1 and the second light amount adjustment device control information C2 with respect to the same target AV value. .

  The first light amount adjusting device control information C1 and the second light amount adjusting device control information C2 may not be a linear function that draws a straight line on the graph, but may be a higher-order function that draws a curve. The first light amount adjusting device control information C1 and the second light amount adjusting device control information C2 are appropriately determined depending on the shape of the blade member 13 and the shape of the cam groove 13.

  The subroutine shown in FIG. 12 is a process for determining which of the first light amount adjustment device control information C1 and the second light amount adjustment device control information C2 is selected when the light amount adjustment device 10 is driven.

  In the subroutine shown in FIG. 12, first, in step S01, it is determined whether or not the imaging device 30 is in the moving image imaging mode. If it is in the moving image capturing mode, the process proceeds to step S05, and the first light amount adjusting device control information C1 is selected.

  If it is determined in step S01 that the mode is not the moving image capturing mode, the process proceeds to step S02. In step S02, it is determined whether or not the imaging apparatus 30 is in the single image capturing mode in which only one still image is captured in response to the release switch 39 being pressed once. When it is in the single image pickup mode, the process proceeds to step S05, and the first light quantity adjustment device control information C1 is selected.

  If it is determined in step S02 that the mode is not the single image pickup mode, the process proceeds to step S03. In step S03, it is determined whether or not the imaging apparatus 30 is in a continuous imaging mode in which still images are continuously captured while the release switch 39 is being pressed. When it is the continuous imaging mode, the process proceeds to step S06, and the second light amount adjustment device control information C2 is selected. If it is determined in step S03 that the image capturing mode is not the continuous imaging mode, the process proceeds to step S05, and the first light amount adjustment device control information C1 is selected.

  As described above, in the subroutine shown in FIG. 12, when the imaging device 30 is in the continuous imaging mode, the second light quantity adjustment device control information C2 is selected, and the imaging mode for other moving image imaging or single imaging is selected. In this case, the first light quantity adjustment device control information C1 is selected.

  In the present embodiment, when the imaging device 30 is in the continuous imaging mode, a stepping motor is used as compared with other imaging modes so that the light amount adjustment device 10 transitions from the open state to the narrowed-down state that is the target AV value in a short time. The rotational speed of 16 is increased. That is, in the present embodiment, the rotation speed of the blade member 13 during the narrowing operation is different between the case of the continuous imaging mode and the case of the other imaging mode, and the rotation speed of the blade member 13 in the continuous imaging mode. Is higher than other imaging modes.

  Here, there are a plurality of blade members 13 as described above, and they overlap each other. For this reason, a frictional force is generated between the plurality of blade members 13. On the other hand, if the rotation speed of the blade member 13 changes, the inertial force of the blade member 13 generated when the blade member 13 rotates also changes in the same manner. Therefore, when the rotational speed of the blade member 13 changes, the relationship between the inertial force of the blade member 13 and the frictional force applied to the blade member 13 changes.

  Thus, the stepping motor 16 is rotated by the same angle by changing the relationship between the inertial force of the blade member 13 and the frictional force applied to the blade member 13 in accordance with the change in the rotation speed of the blade member 13. Even in this case, the actual stop position of the blade member 13 will be different depending on the change in the rotation speed of the stepping motor 16.

  Therefore, in the imaging device 30 of the present embodiment, as described above, when the stepping motor 16 is moved at a high speed, that is, in the continuous imaging mode in which the blade member 13 is rotated at a high speed, the stepping motor 16 is moved at a relatively low speed. The number of drive pulse signals for a certain target AV value is reduced as compared with other imaging modes that are moved by.

  That is, in the present embodiment, in the continuous imaging mode in which the blade member 13 is rotated at high speed, the blade member 13 is expected to move more greatly due to the inertial force when stopped, and the stepping motor 16 rotates with respect to a predetermined target AV value. The moving angle is made smaller than in other imaging modes. Accordingly, even in the continuous imaging mode in which the blade member 13 is rotated at high speed, the blade member 13 can be stopped approximately accurately at a position where the target AV value is obtained.

  Further, in the present embodiment, when the imaging device 30 is in the single image capturing mode or the moving image capturing mode, the operation sound of the light amount adjusting device 10 that suppresses the operation of the light amount adjusting device 10 that only needs to be rotated at a relatively low speed, Silence can be increased.

  As described above, the imaging apparatus 30 of the present embodiment realizes an increase in the number of continuously shot images per unit time in the continuous shooting mode and an improvement in quietness in the single shooting mode and the moving image shooting mode. Is possible.

  Note that the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist or concept of the invention that can be read from the claims and the entire specification. The apparatus is also included in the technical scope of the present invention.

  Needless to say, the light amount adjustment device according to the present invention is not limited to a form provided in a so-called still camera, but may be provided in an electronic apparatus having an imaging function such as a video camera or a mobile communication terminal.

10 Light quantity adjustment device,
10a opening,
11 Fixed frame member,
11a opening,
11b through groove,
11d screw hole,
11c Coil spring locking part,
11f through hole,
11m outer wall surface,
11n inner wall surface,
11p circular plane part,
12 Rotation drive plate,
12b Coil spring locking part A,
12c cam groove,
12d sector gear,
12e shading blade,
13 blade member,
13a main blade part,
13c driven pin,
13d through hole,
13e Torsion spring locking part,
13h support part,
13i edge,
14 Lid member,
14a opening,
14b bottomed groove,
14c Notch,
14d Torsion spring locking part A,
14e spring support shaft,
15 Torsion spring,
15a other arm,
15b one arm,
15c body part,
16 Stepping motor,
16a pinion gear,
17 screws,
18 Biasing spring,
19 Screw,
20 position sensor,
21 lens device,
22 Imaging lens,
23 Lens control unit,
25 storage unit,
24 focus lens drive unit,
26 communication unit 30 imaging device,
31 Camera body,
32 image sensor,
33 Power supply,
34 control unit,
35 storage device,
36 image display device,
37 Touch panel (operation member),
38 Lens communication section,
39 Release switch,
40 Power switch,
C1 first light quantity adjustment device control information,
C2 second light quantity adjustment device control information,
L Optical axis.

Claims (3)

A lens device;
The aperture of the opening formed by each edge of the plurality of blade members can be changed by driving the plurality of blade members arranged around the optical axis by a stepping motor provided in the lens device. A light amount adjusting device;
A controller that outputs a drive pulse signal for driving the stepping motor;
An imaging device comprising:
A memory for storing the first light amount adjusting device control information and the second light amount adjusting device control information representing the relationship between the target AV value for controlling the light amount adjusting device and the number of drive pulse signals input to the stepping motor. Part
The control unit controls the light amount adjusting device using the second light amount adjusting device control information when continuously capturing still images with the image capturing device, and captures a moving image with the image capturing device or still images. In the case where only one image is picked up, the light amount adjusting device is controlled using the second light amount adjusting device control information.   The number of drive pulse signals according to the first light quantity adjustment device control information is greater than the number of drive pulse signals according to the second light quantity adjustment device control information when the target AV value is the same. Imaging device.   The imaging apparatus according to claim 1, wherein the plurality of blade members are urged in a direction of decreasing the aperture diameter by a plurality of torsion springs engaged with each of the plurality of blade members.

Images